Sensitivity analysis of near solidus forming (NSF) process with digital twin using Taguchi approach

doi:10.1007/s40436-024-00482-4

Abstract

Abstract: Forging at near solidus material state takes advantage of the high ductility of the material at the semi solid or soft-solid state while keeping most of the mechanical properties of a forged part. The technology is at maturity level ready for its industrial implementation. However, to implement the process for complex cases the development of an appropriate digital twin (DT) is necessary. While developing a material model, a strong experimental and DT is necessary to be able to evaluate the accuracy of the model. Aimed at having a reliable DT under control, for future material model validations, the main objective of this work is to develop a sensitivity analysis of three NSF industrial cases such as Hook, R spindle and H spindle to develop an adequate DT calibration procedure. Firstly, the benchmark experimentation process parameter noise and experimentation boundary conditions (BCs) parameter uncertainty are identified. Secondly, the three industrial benchmark DTs are constructed, and a Taguchi design of experiments (DoEs) methodology is put in place to develop the sensitivity analysis. Finally, after simulations the results are critically evaluated and the sensitivity of each benchmark to the different inputs (process parameter noise and BC parameter uncertainty) is studied. Lastly, the optimum DT calibration procedure is developed. Overall, the results stated the minimum impact of the material model in terms of dies filling. Nevertheless, even if the material model is the highest impacting factor for the forging forces other inputs, such as heat transfer and friction must be under control first.

The full text can be downloaded at https://link.springer.com/article/10.1007/s40436-024-00482-4

Key words: Near solidus, Digital twin (DT), Taguchi design, Sensitivity analysis, Heat transfer

Muhammad Sajjad, Javier Trinidad, Gorka Plata, Jokin Lozares, Joseba Mendiguren. Sensitivity analysis of near solidus forming (NSF) process with digital twin using Taguchi approach[J]. Advances in Manufacturing, 2025, 13(2): 322-336.

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References

[1] Ducato A, Buffa G, Fratini L et al (2015) Dual phase titanium alloy hot forging process design: experiments and numerical modeling. Adv Manuf 3:269-281
[2] Turan E, Konuşkan Y, Yıldırım N et al (2022) Digital twin modelling for optimizing the material consumption: a case study on sustainability improvement of thermoforming process. Sustain Comput Inform Syst 35:100655. https://doi.org/10.1016/j.suscom.2022.100655
[3] Murali S, Yong MS (2010) Liquid forging of thin Al-Si structures. J Mater Process Technol 210:1276-1281
[4] Bayramoglu M, Polat H, Geren N (2008) Cost and performance evaluation of different surface treated dies for hot forging process. J Mater Process Technol 205:394-403
[5] Kirkwood DH (1994) Semisolid metal processing. Int Mater Rev 39:173-189
[6] Fan Z (2002) Semisolid metal processing. Int Mater Rev 47:49-86
[7] Liu K, Chen XG (2019) Influence of the modification of iron-bearing intermetallic and eutectic Si on the mechanical behavior near the solidus temperature in Al-Si-Cu 319 cast alloy. Physica B Condens Matter 560:126-132
[8] Lozares J, Plata G, Hurtado I et al (2020) Near solidus forming (NSF): semi-solid steel forming at high solid content to obtain as-forged properties. Metals (Basel) 10(2):198. https://doi.org/10.3390/met10020198
[9] Plata G, Lozares J, Sánchez A et al (2020) Preliminary study on the capability of the novel near solidus forming (NSF) technology to manufacture complex steel components. Materials 13(20):4682. https://doi.org/10.3390/ma13204682
[10] Rogal DJ, Atkinson HV et al (2013) Characterization of semi-solid processing of aluminium alloy 7075 with Sc and Zr additions. Mater Sci Eng A 580:362-373
[11] Psarommatis F, May G (2023) A literature review and design methodology for digital twins in the era of zero defect manufacturing. Int J Prod Res 61:5723-5743
[12] Scaglioni B, Ferretti G (2018) Towards digital twins through object-oriented modelling: a machine tool case study. IFAC-PapersOnLine 51:613-618
[13] Hürkamp A, Lorenz R, Ossowski T et al (2021) Simulation-based digital twin for the manufacturing of thermoplastic composites. Procedia CIRP 100:1-6
[14] Knust J, Podszus F, Stonis M et al (2017) Preform optimization for hot forging processes using genetic algorithms. Int J Adv Manuf Technol 89:1623-1634
[15] Sołek KP, Łukaszek-Sołek A, Kuziak R (2009) Rheological properties of alloys near solidus point intended for thixoforming. Arch Civ Mech Eng 9:111-117
[16] Hopmann C, Klein J, Schöngart M (2016) Determination of the strain rate dependent thermal softening behavior of thermoplastic materials for crash simulations. In: AIP conference proceedings. American Institute of Physics Inc, South Korea
[17] Monajati H, Jahazi M, Yue S et al (2005) Deformation characteristics of isothermally forged UDIMET 720 Nickel-base superalloy. Metall Mater Trans A 36:895-905
[18] Subroto T, Miroux A, Eskin DG et al (2017) Tensile mechanical properties, constitutive parameters and fracture characteristics of an as-cast AA7050 alloy in the near-solidus temperature regime. Mater Sci Eng, A 679:28-35
[19] Malinowski Z, Lenard JG, Davies ME (1994) A study of the heat-transfer coefficient as a function of temperature and pressure. J Mater Process Technol 41:125-142
[20] Burte PR, Im YT, Altan T et al (1990) Measurement and analysis of heat transfer and friction during hot forging. J Manuf Sci Eng 112:332-339
[21] Sethy R, Galdos L, Mendiguren J et al (2016) Investigation of influencing factors on friction during ring test in hot forging using FEM simulation. In: AIP conference proceedings. American Institute of Physics Inc, Nantes
[22] Becker E, Favier V, Bigot R et al (2010) Impact of experimental conditions on material response during forming of steel in semi-solid state. J Mater Process Technol 210:1482-1492
[23] Barrau O, Boher C, Vergne C et al (2002) Investigations of friction and wear mechanisms of hot forging tool steels. In: 6th International tooling conference, vol 2001, pp 95-111
[24] Bogdan O (2012) Influence of ingot size and mold design on macro-segregation in AISI 4340 forging ingots. In: Proceedings of the 1st international conference on ingot casting, rolling and forging, Aachen, Germany
[25] Traidi K, Favier V, Lestriez P et al (2016) Thermomechanical steels behaviors at semi-solid state. In: AIP conference proceedings. American Institute of Physics Inc, Nantes
[26] Andrade-Campos A, Teixeira-Dias F, Krupp U et al (2010) Effect of strain rate, adiabatic heating and phase transformation phenomena on the mechanical behaviour of stainless steel. Strain 46:283-297
[27] Tirth V, Arabi A (2020) Effect of liquid forging pressure on solubility and freezing coefficients of cast aluminum 2124, 2218 and 6063 alloys. Arch Metall Mater 65:357-366
[28] Koc M, Vazquez V, Witulski T et al (1996) Materials processing technology application of the finite element method to predict material flow and defects in the semi-solid forging of A356 aluminum alloys. J Mater Process Technol 59:106-112
[29] Mills KC (2005) Measurement and estimation of physical properties of metals at high temperatures. In: Fundamentals of metallurgy. Elsevier, pp 109-177
[30] He B, Bai KJ (2021) Digital twin-based sustainable intelligent manufacturing: a review. Adv Manuf 9:1-21
[31] Slater C, Plata G, Sánchez A et al (2020) A novel forming technique to coforge bimetal components into complex geometries. Manuf Lett 26:21-24
[32] Zhang DW, Li SP, Jing F et al (2018) Initial position optimization of preform for large-scale strut forging. Int J Adv Manuf Technol 94:2803-2810
[33] Murillo-Marrodan A, Garcia E, Cortes F (2018) A study of friction model performance in a skew rolling process numerical simulation. Int J Simul Modell 17:569-582
[34] Rosa JL, Robin A, Silva MB et al (2009) Electrodeposition of copper on titanium wires: Taguchi experimental design approach. J Mater Process Technol 209:1181-1188
[35] Zhang J, Wu D, Zhou J et al (2014) Multi-objective optimization of process parameters for 7050 aluminum alloy rib-web forgings’ precise forming based on Taguchi method. In: Procedia engineering. Elsevier Ltd, Nagoya, pp 558-563
[36] Equbal MI, Kumar R, Shamim M et al (2014) A grey-based Taguchi method to optimize hot forging process. Procedia Mater Sci 6:1495-1504
[37] Hallstrom J (2000) Influence of friction on die filling in counterblow hammer forging. J Mater Process Technol 108:21-25
[38] Hawryluk M, Jakubik J (2016) Analysis of forging defects for selected industrial die forging processes. Eng Fail Anal 59:396-409
[39] Vazquez V, Altan T (2000) Die design for flashless forging of complex parts. J Mater Process Technol 98:81-89
[40] Mendiguren J, Ortubay R, De Argandonã ES et al (2016) Experimental characterization of the heat transfer coefficient under different close loop controlled pressures and die temperatures. Appl Therm Eng 99:813-824